Browsing by Subject "Aromatase"
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Item DVL regulation of tissue-specific aromatase transcripts in breast cancer(Impact Journals, 2018-12-25) O'Hagan, Heather M.; Medical Sciences, IU School of MedicineItem Interactions of Aromatase and Seladin-1: A Neurosteroidogenic and Gender Perspective(De Gruyter, 2019-11-06) Kelicen-Ugur, Pelin; Cincioğlu-Palabıyık, Mehtap; Çelik, Hande; Karahan, Hande; Medical and Molecular Genetics, School of MedicineAromatase and seladin-1 are enzymes that have major roles in estrogen synthesis and are important in both brain physiology and pathology. Aromatase is the key enzyme that catalyzes estrogen biosynthesis from androgen precursors and regulates the brain's neurosteroidogenic activity. Seladin-1 is the enzyme that catalyzes the last step in the biosynthesis of cholesterol, the precursor of all hormones, from desmosterol. Studies indicated that seladin-1 is a downstream mediator of the neuroprotective activity of estrogen. Recently, we also showed that there is an interaction between aromatase and seladin-1 in the brain. Therefore, the expression of local brain aromatase and seladin-1 is important, as they produce neuroactive steroids in the brain for the protection of neuronal damage. Increasing steroid biosynthesis specifically in the central nervous system (CNS) without affecting peripheral hormone levels may be possible by manipulating brain-specific promoters of steroidogenic enzymes. This review emphasizes that local estrogen, rather than plasma estrogen, may be responsible for estrogens' protective effects in the brain. Therefore, the roles of aromatase and seladin-1 and their interactions in neurodegenerative events such as Alzheimer's disease (AD), ischemia/reperfusion injury (stroke), and epilepsy are also discussed in this review.Item A translational bioinformatic approach in identifying and validating an interaction between Vitamin A and CYP19A1(Springer (Biomed Central Ltd.), 2015) Philips, Santosh; Zhou, Jing; Li, Zhigao; Skaar, Todd C.; Li, Lang; Department of Medicine, IU School of MedicineINTRODUCTION: One major challenge in personalized medicine research is to identify the environmental factors that can alter drug response, and to investigate their molecular mechanisms. These environmental factors include co-medications, food, and nutrition or dietary supplements. The increasing use of dietary supplements and their potential interactions with cytochrome P450 (CYP450) enzymes is a highly significant personalized medicine research domain, because most of the drugs on the market are metabolized through CYP450 enzymes. METHODS: Initial bioinformatics analysis revealed a number of regulators of CYP450 enzymes from a human liver bank gene expression quantitative loci data set. Then, a compound-gene network was constructed from the curated literature data. This network consisted of compounds that interact with either CYPs and/or their regulators that influence either their gene expression or activity. We further evaluated this finding in three different cell lines: JEG3, HeLa, and LNCaP cells. RESULTS: From a total of 868 interactions we were able to identify an interesting interaction between retinoic acid (i.e. Vitamin A) and the aromatase gene (i.e. CYP19A1). Our experimental results showed that retinoic acid at physiological concentration significantly influenced CYP19A1 gene expressions. CONCLUSIONS: These results suggest that the presence of retinoic acid may alter the efficacy of agents used to suppress aromatase expression.Item Understanding Aromatase: A Mechanistic Basis for Drug Interactions and New Inhibitors(2012-03-16) Lu, Wenjie; Flockhart, David A.; Desta, Zeruesenay; Queener, Sherry F.; Vasko, Michael R.; Zhang, Jian-TingAromatase is the cytochrome P450 enzyme that converts androgens to estrogens. Aromatase is the target of the aromatase inhibitor class of drugs widely used to treat estrogen-mediated conditions including breast cancer. Little is known about the role of this enzyme in drug metabolism or in drug interactions. Since this lack of knowledge has been an impediment to optimal therapy, it is important to understand these roles of aromatase. Therefore, a comprehensive series of studies was carried out to characterize its ability to metabolize drugs and its susceptibility to inhibition by xenobiotics. The overall objective of this work was to better understand the interactions of small molecules with aromatase and to use this new knowledge to predict aromatase-mediated drug interactions and anticipate novel molecular structures that interact with the enzyme. Aromatase was shown to be a drug metabolizing enzyme able to metabolize methadone both in vitro (Km of 314 μM) and in vivo (22% of methadone clearance). A number of novel aromatase inhibitors that employ diverse kinetic mechanisms were identified. These include a potent competitive inhibitor: norendoxifen (Ki of 35 nM), two non-competitive inhibitors: endoxifen (Ki of 4.0 μM) and N-desmethyl-tamoxifen (Ki of 15.9 μM), a mechanism-based inhibitor: methadone (KI of 40.6 ± 2.8 μM; kinact of 0.061 ± 0.001 min-1), and a stereoselective inhibitor: naringenin (IC50s of 2.8 μM for (R)-enatiomer and 1.4 μM for (S)-enatiomer). Through investigation of the structure-potency relationships so discovered, a series of new biochemical structures to be exploited as aromatase inhibitors were identified. These studies have identified new roles for aromatase as a catalyst for methadone metabolism and as a mediator of the effects of tamoxifen by demonstrating that a number of its metabolites can act as aromatase inhibitors. This work also provides a new mechanistic framework for the design of novel aromatase inhibitors that can be used in breast cancer. Overall, the data suggest ways to more consistently treat breast cancer with current medications, to better anticipate drug interactions, and therefore to improve the quality of life of patients in ways that minimize side effects, while optimizing therapeutic benefits, in each person treated.